Hyperpolarization-activated cyclic nucleotide- gated cation (HCN) channels play a critical role in the control of pacemaking in the heart and repetitive firing in neurons. In HCN channels, the intracellular cyclic nucleotide- binding domain (CNBD) is connected to the transmembrane portion of the channel (TMPC) through a helical domain, the C-linker. Although this domain is critical for mechanical signal transduction, the conformational dynamics in the C-linker that transmit the nucleotide-binding signal to the HCN channel pore are unknown. Here, we use linear response theory to analyze conformational changes in the C-linker of the human HCN1 protein, which couple cAMP binding in the CNBD with gating in the TMPC. By applying a force to the tip of the so-called "elbow" of the C-linker, the coarse-grained calculations recapitulate the same conformational changes triggered by cAMP binding in experimental studies. Furthermore, in our simulations, a displacement of the C-linker parallel to the membrane plane (i.e. horizontally) induced a rotational movement resulting in a distinct tilting of the transmembrane helices. This movement, in turn, increased the distance between the voltage-sensing S4 domain and the surrounding transmembrane domains and led to a widening of the intracellular channel gate. In conclusion, our computational approach, combined with experimental data, thus provides a more detailed understanding of how cAMP binding is mechanically coupled over long distances to promote voltage-dependent opening of HCN channels. © 2018 Gross et al. Published by The American Society for Biochemistry and Molecular Biology, Inc.

Mechanical transduction of cytoplasmic-to-transmembrane-domain movements in a hyperpolarization-activated cyclic nucleotide-gated cation channel

Moroni A;
2018

Abstract

Hyperpolarization-activated cyclic nucleotide- gated cation (HCN) channels play a critical role in the control of pacemaking in the heart and repetitive firing in neurons. In HCN channels, the intracellular cyclic nucleotide- binding domain (CNBD) is connected to the transmembrane portion of the channel (TMPC) through a helical domain, the C-linker. Although this domain is critical for mechanical signal transduction, the conformational dynamics in the C-linker that transmit the nucleotide-binding signal to the HCN channel pore are unknown. Here, we use linear response theory to analyze conformational changes in the C-linker of the human HCN1 protein, which couple cAMP binding in the CNBD with gating in the TMPC. By applying a force to the tip of the so-called "elbow" of the C-linker, the coarse-grained calculations recapitulate the same conformational changes triggered by cAMP binding in experimental studies. Furthermore, in our simulations, a displacement of the C-linker parallel to the membrane plane (i.e. horizontally) induced a rotational movement resulting in a distinct tilting of the transmembrane helices. This movement, in turn, increased the distance between the voltage-sensing S4 domain and the surrounding transmembrane domains and led to a widening of the intracellular channel gate. In conclusion, our computational approach, combined with experimental data, thus provides a more detailed understanding of how cAMP binding is mechanically coupled over long distances to promote voltage-dependent opening of HCN channels. © 2018 Gross et al. Published by The American Society for Biochemistry and Molecular Biology, Inc.
2018
Istituto di Biofisica - IBF
Activation analysis
Bacteriophages
Cell proliferation
Computation theory
Positive ions
Signal transduction
Computational approach
Conformational change
Conformational dynamics
Intracellular channel
Linear-response theory
Rotational movement
Trans-membrane domains
Transmembrane helices
Nucleotides
cyclic AMP
cyclic nucleotide gated channel
membrane protein
protein HCN1
unclassified drug
cyclic AMP
HCN1 protein
human
hyperpolarization activated cyclic nucleotide gated channel
potassium channel
Article
calculation
channel gat
conformational transition
controlled study
hyperpolarization
ligand binding
phase transition
priority journal
protein domain
signal transduction
simulation
structure analysis
cell membrane
chemical model
chemistry
human
metabolism
Cell Membrane
Cyclic AMP
Humans
Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels
Models
Chemical
Potassium Channels
Protein Domains
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/395290
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